Image decoding apparatus and method

ABSTRACT

According to an embodiment, an image decoding apparatus includes a memory, a decoder and a first filter. The memory stores reference pixels based on pixels included in a decoded pixel block. The decoder decodes encoded data in units of pixel blocks using the reference pixels to generate a first decoded pixel block, the first decoded pixel block being adjacent to the reference pixels. The first filter performs a first filtering on only the first decoded pixel block using the first decoded pixel block and part of the reference pixels perpendicularly adjacent to the first decoded pixel block in a scan direction of image decoding processing.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based upon and claims the benefit of priority fromJapanese Patent Application No. 2015-089710, filed Apr. 24, 2015, theentire contents of which are incorporated herein by reference.

FIELD

Embodiments described herein relate generally to an image decodingapparatus and method.

BACKGROUND

It is known that block distortion that is perceived in a shape of pixelblocks occurs in a decoded image obtained by decoding the pixel blocksencoded in units of blocks. Such block distortion deteriorates asubjective image quality. Deblocking filters have been presented as amethod for reducing such distortion.

Deblocking filters have been introduced into the moving imagecompression encoding standards such as H.264/AVC (ITU-T H.264|ISO/IEC14496-10 Advanced Video Coding) and H.265/HEVC (ITU-T H.265|ISO/IEC23008-2 High Efficiency Video Coding). Deblocking filters used in thesestandards perform filtering to change the pixel values for therespective pixels adjacent to the boundary of the pixel block. Becauseimage decoding apparatuses equipped with such deblocking filters alsoperform filtering on a pixel block that is positioned on the upper sideof the pixel block being processed, output delay occurs.

A method is known as another image decoding apparatus. In the method,pixel values are referred to in the deblocking filter, and the pixels onwhich processing is performed are reduced. The image decoding apparatuscan reduce the scale of the memory circuit and simplify the processing,but requires an independent memory for referring to pixels necessary forfiltering. In addition, the image decoding apparatus still causes theoutput delay described above.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating an image decoding apparatusaccording to a first embodiment;

FIG. 2 is a diagram illustrating a method for intra prediction of 4×4pixels in H.264/AVC;

FIG. 3 is a diagram illustrating a positional relation between a pixelblock and a reference line memory;

FIG. 4 is a block diagram illustrating an image decoding apparatuscorresponding to a modification of the image decoding apparatusaccording to the first embodiment;

FIG. 5 is a diagram illustrating a positional relation between a pixelblock Q and a pixel block P decoded directly before the pixel block Q;

FIG. 6 is a block diagram illustrating an image decoding apparatusaccording to a second embodiment;

FIG. 7A is a diagram illustrating a positional relation of pixels usedin a calculator in FIG. 6;

FIG. 7B is a diagram illustrating a positional relation of pixels usedin the calculator in FIG. 6;

FIG. 8 is a block diagram illustrating an image decoding apparatusaccording to a third embodiment; and

FIG. 9 is a diagram illustrating a positional relation of pixels used ina calculator in FIG. 8.

DETAILED DESCRIPTION

Embodiments will be explained hereinafter with reference to thedrawings.

According to an embodiment, an image decoding apparatus includes amemory, a decoder and a first filter. The memory stores reference pixelsbased on pixels included in a decoded pixel block. The decoder decodesencoded data in units of pixel blocks using the reference pixels togenerate a first decoded pixel block, the first decoded pixel blockbeing adjacent to the reference pixels. The first filter performs afirst filtering on only the first decoded pixel block using the firstdecoded pixel block and part of the reference pixels perpendicularlyadjacent to the first decoded pixel block in a scan direction of imagedecoding processing.

In the following explanation, constituent elements that are the same asor similar to the explained elements will be denoted by the same orsimilar reference numerals, and overlapping explanation thereof will bebasically omitted.

In the following explanation, suppose that processing is performed onunits of pixel blocks of 4×4 pixels, and processing is performed in theorder of raster scan as the processing order (also referred to as scandirection). The processing in the order of raster scan indicatesperforming processing in units of pixel blocks from the upper left ofthe image in the right direction, moving to the next lower pixel blockwhen the processing is performed to the upper right part, and performingprocessing from the left to the right in the same manner.

However, the size of the pixel block and the processing order are notlimited thereto, but processing may be performed with various sizes andin various processing orders. For example, the size of the pixel blockmay be the size of macroblocks, each of which is formed of a pluralityof pixel blocks and used in H. 264/AVC or the like. In addition, thepixel blocks may be processed in the processing order in which the pixelblocks are processed from the upper right of the image in the lowerdirection, and the processing is moved to the next left block when theprocessing is performed to the lower right part, and processing isperformed from the top block to the bottom block in the same manner. Asanother example, the processing may be performed in the order of aspiral pattern starting from the pixel block located around the centerof the picture.

In addition, the terms indicating the positional relation such as“upper”, “lower”, “left”, “perpendicular”, and “horizontal” aredescribed based on the processing in the order of the raster scan.However, the terms indicating the positional relations may be properlychanged according to the processing order or the direction in which theimage is viewed.

First Embodiment

As illustrated in FIG. 1, an image decoding apparatus 100 according to afirst embodiment includes a decoder 101, a reference line memory 102,and a filter 103. The image decoding apparatus 100 is implemented by acircuit that performs decoding processing performed by the decoder 101,an image decoding LSI formed of an SRAM and a DRAM serving as thereference line memory 102, and a circuit that performs filteringperformed by the filter 103.

The decoder 101 receives encoded data encoded in units of pixel blocks.The decoder 101 decodes the encoded data in units of pixel blocks usingreference pixels (described later) based on pixels included in a pixelblock that has already been decoded, to generate a decoded pixel block.The decoder 101 outputs the decoded pixel block to the reference linememory 102 and the filter 103. Otherwise, the decoder 101 may outputpart of pixels included in the decoded pixel block to the reference linememory 102.

Specifically, the decoder 101 refers to reference pixels located on theupper side of the pixel block to be decoded and pixels included in thepreviously decoded pixel block and located on the left of the pixelblock to be decoded, and generates a predicted pixel block from theencoded data. The decoder 101 also adds a residual pixel block decodedby using the encoded data to the predicted pixel block, to generate adecoded pixel block. The pixels included in the previously decoded pixelblock may be stored in a temporary buffer (such as a flip-flop) of thedecoder 101. In the following description, explanation of the processingrelated to generation of a predicted pixel block and a residual pixelblock in the decoder 101 will be omitted, because the processing can beachieved by using a general method used in image decoding processing.

For example, as illustrated in FIG. 2, the decoder 101 may performdecoding processing using an intra prediction method of 4×4 pixels usedin H. 264/AVC. FIG. 2 illustrates a method of referring to pixels(shaded pixels in FIG. 2) adjacent to a pixel block of 4×4 pixels, andpredicting pixels of the pixel block along the directions of arrows fromthe respective shaded pixels indicating starting points of the arrows,and a method of predicting the pixels from the average value of thepixel block.

Otherwise, the decoder 101 may perform decoding processing using variousintra prediction methods used in H.264/AVC or H.265/HEVC. The decoder101 may perform decoding processing using another prediction method(such as inter-picture prediction) for part of the pixel block.

The reference line memory 102 receives the decoded pixel block from thedecoder 101. Otherwise, the reference line memory 102 may receive partof the pixels included in the decoded pixel block from the decoder 101.The reference line memory 102 stores reference pixels based on the pixelincluded in the decoded pixel block. The reference line memory 102outputs the reference pixels to the decoder 101 and the filter 103.

Specifically, as reference pixels, the reference line memory 102 storesat least one line of pixels extending in a scan direction and closest tothe pixel block that is not decoded (referred to as a non-decoded pixelblock), that is, a one-pixel line. Otherwise, the reference line memory102 may store two-pixel lines as reference pixels. A line of pixels inthe scan direction is also referred to as a pixel line hereinafter. Thereference line memory 102 may be mounted as, for example, asemiconductor storage device (such as an SRAM and a DRAM).

The filter 103 receives the decoded pixel block from the decoder 101,and receives reference pixels from the reference line memory 102. Thefilter 103 performs filtering on the decoded pixel block using thedecoded pixel block and part of the reference pixels that areperpendicularly adjacent to the decoded pixel block in the scandirection of the image decoding processing. The term “perpendicularlyadjacent to” means being adjacent in the perpendicular direction in thepicture. The filter 103 should use at least one line of pixels extendingin the scan direction and closest to the decoded pixel block, among thereference pixels. The filter 103 outputs the filtered decoded pixelblock to an external device (such as an output buffer and a displaydevice) that is not illustrated, as an output pixel block.

Specifically, the filter 103 performs filtering on a decoded pixel blockQ of 4×4 pixels using a pixel line P of 1×4 pixels, as illustrated inFIG. 3. Luminance information of pixels (hereinafter referred to as“pixel value”) or the like may be used in the filtering. P(0, 0)illustrated in FIG. 3 indicates a pixel value of a pixel at the position(0, 0) of the pixel line P, and Q(0, 0) indicates a pixel value of apixel in the position (0, 0) of the decoded pixel block Q. In thefollowing description, a position of a pixel is indicated as “(X, Y)”.The filter 103 may perform filtering on pixels included in the pixelblock, for example, in accordance with the following Expression (1).

$\begin{matrix}{{Q^{\prime}\left( {X,Y} \right)} = {{clip}\left( {\frac{{{a(Y)}*{P\left( {X,0} \right)}} + {\sum\limits_{y = 0}^{3}\left( {{b\left( {Y,y} \right)}*{Q\left( {X,y} \right)}} \right)} + {c(Y)}}{{a(Y)} + {\sum\limits_{y = 0}^{3}{b\left( {Y,y} \right)}}},{{Q\left( {X,Y} \right)} - {tc}},{{Q\left( {X,Y} \right)} + {tc}}} \right)}} & (1)\end{matrix}$

In the Expression (1), Q′(X, Y) on the left side indicates Q(X, Y)filtered by using P(X, 0). The clip(A, B, C) on the right side indicatesclipping a calculated value A with a lower limit value B and an upperlimit value C. The calculated value A indicates a pixel value calculatedfrom the filtered pixel. The lower limit value B indicates a valueobtained by subtracting a predetermined value tc from a pixel value(Q(X, Y)) of the pixel before filtering. The upper limit value Cindicates a value obtained by adding the predetermined value tc to Q(X,Y).

In the expression of the calculated value A, a(Y) indicates acoefficient for P(X, 0), b(Y, y) indicates a coefficient for Q(X, y),and c(Y) indicates an offset in the position of a pixel Y. Thecoefficient a(Y) is determined by (Y) of Q(X, Y) to be filtered, and thecoefficient b(Y, y) is determined by (Y) of Q(X, Y) to be filtered and(y) of Q(X, y) to be referred to. In the expression of the lower limitvalue B and the expression of the upper limit value C, tc is a valuethat is defined by the lower limit value B and the upper limit value C,and defines a variation width of the pixel value that is changed byfiltering.

The above coefficients and the offset are designed such that thefiltering based on the Expression (1) is achieved by a low-pass filter.The coefficients may be designed to prevent change of part of thepixels. All the coefficients may be set to 1, for example, to operatethe filter as an average value filter. For example, the predeterminedvalue tc may be set in the same manner as the value used in a deblockingfilter of H.264/AVC and H.265/HEVC. Specifically, the predeterminedvalue tc may be calculated based on parameters for controllingquantization of each adjacent pixel block used in the decoder 101.

To sum up, the filter 103 is capable of suppressing distortion betweenthe decoded pixel block and an upper pixel block adjacent to the decodedpixel block (that is, distortion in the horizontal direction) byperforming filtering to serve as a low pass filter. The clipping in theExpression (1) may be omitted, and the calculated value A may be used asQ′(X, Y) without any processing.

FIG. 4 illustrates an image decoding apparatus 200 serving as amodification of the image decoding apparatus 100 according to the firstembodiment. The image decoding apparatus 200 includes the decoder 101,the reference line memory 102, a first filter 201, and a second filter202. The second filter 202 corresponds to the filter 103 of the imagedecoding apparatus 100. The image decoding apparatus 200 is differentfrom the image decoding apparatus 100, in that the first filter 201 isadded between the decoder 101 and the second filter 202. The followingis an explanation of differences in operations in the units of the imagedecoding apparatus 200.

The decoder 101 decodes encoded data in units of pixel blocks usingreference pixels to generate a decoded pixel block (a first decodedpixel block). The decoder 101 outputs the first decoded pixel block tothe reference line memory 102 and the first filter 201. The decoder 101also outputs the first decoded pixel block to the second filter 202 viathe first filter 201. The decoder 101 may directly output the firstdecoded pixel block to the second filter 202.

The reference line memory 102 outputs reference pixels to the decoder101 and the second filter 202.

The first filter 201 receives the first decoded pixel block from thedecoder 101. The first filter 201 performs first filtering on the firstdecoded pixel block using the first decoded pixel block and a seconddecoded pixel block decoded directly before the first decoded pixelblock, stored in the temporary buffer of the decoder 101, and adjacentto the first decoded pixel block. The first filter 201 outputs the firstdecoded pixel block on which the first filtering is performed to thesecond filter 202.

For example, the first filter 201 may perform an operation that is thesame as, or similar to, the operation of a horizontal deblocking filterused in H.264/AVC or H.265/HEVC. Specifically, the first filter 201performs filtering on a decoded pixel block Q of 4×4 pixels using thepreviously decoded pixel block P of 4×4 pixels. The first filter 201 mayperform filtering on pixels included in the pixel block, for example, inaccordance with the following Expression (2).

$\begin{matrix}{{Q^{\prime}\left( {X,Y} \right)} = {{clip}\left( {\frac{{\sum\limits_{y = 0}^{3}\left( {{d\left( {Y,y} \right)}*{P\left( {X,y} \right)}} \right)} + {\sum\limits_{y = 0}^{3}\left( {{e\left( {Y,y} \right)}*{Q\left( {X,y} \right)}} \right)} + {f(Y)}}{\sum\limits_{y = 0}^{3}\left( {{d\left( {Y,y} \right)} + {e\left( {Y,y} \right)}} \right)},{{Q\left( {X,Y} \right)} - {tc}},{{Q\left( {X,Y} \right)} + {tc}}} \right)}} & (2)\end{matrix}$

In the Expression (2), Q′(X, Y) on the left side indicates Q(X, Y)filtered by using P(X, y). The clip(A, B, C) on the right side indicatesclipping performed in the same manner as the Expression (1).

In the expression of the calculated value A, d(Y, y) indicates acoefficient for P(X, y), e(Y, y) indicates a coefficient for Q(X, y),and f(Y) indicates an offset in the position of a pixel Y. Thecoefficients d(Y, y) and e(Y, y) are determined by (Y) of Q(X, Y) to befiltered and (y) of Q(X, y) to be referred to, respectively. In theexpression of the lower limit value B and the expression of the upperlimit value C, tc is a value that is defined by the lower limit value Band the upper limit value C, and defines a variation width of the pixelvalue that is changed by filtering.

The coefficients and the offset are designed such that the filteringbased on the Expression (2) is achieved by a low-pass filter. The abovecoefficients may be designed to prevent change of part of the pixels.All the above coefficients may be set to 1, for example, to operate thefilter as an average value filter. For example, the predetermined valuetc may be set in the same manner as the value used in a deblockingfilter of H.264/AVC and H.265/HEVC. Specifically, the predeterminedvalue tc may be calculated based on parameters for controllingquantization of each adjacent pixel block used in the decoder 101.

The first filter 201 may further perform first filtering on a previousdecoded pixel block which is located on the left of the first decodedpixel block and on which filtering is performed. The previous decodedpixel block is stored in a temporary buffer (such as a flip-flop) of thefirst filter 201.

To sum up, the first filter 201 is capable of suppressing distortionbetween the decoded pixel block and a left pixel block adjacent to thedecoded pixel block (that is, distortion in the perpendiculardirection).

The second filter 202 receives a first decoded pixel block from thedecoder 101, receives reference pixels from the reference line memory102, and receives the first decoded pixel block on which the firstfiltering is performed from the first filter 201. The second filter 202further performs filtering on the first decoded pixel block on which thefirst filtering is performed. Specific operations thereof are the sameas those in the filter 103 of the image decoding apparatus 100, andexplanation thereof is omitted. The second filter 202 outputs thedecoded pixel block on which a plurality of processes are performed toan external device that is not illustrated, as the output pixel block.The second filter 202 may be disposed at a previous stage of the firstfilter 201, and the order of the filtering may be different.

As described above, the filter of the image decoding apparatus accordingto the first embodiment uses the reference pixels that are stored in thereference line memory and used for decoding processing also asinformation of pixels that are adjacent to the upper part of the decodedpixel block. With this structure, the image decoding apparatus needs noadditional line memory for filtering, and enables suppression of anincrease in the scale of the memory circuit.

In addition, in the image decoding apparatus according to the firstembodiment, no filtering is performed on a pixel block located on theupper side of the decoded pixel block in filtering on the decoded pixelblock. Accordingly, the image decoding apparatus is capable of instantlyoutputting a filtered pixel block, and enables suppression of outputdelay of the output pixel block.

Second Embodiment

As illustrated in FIG. 6, an image decoding apparatus 300 according to asecond embodiment includes a decoder 101, a reference line memory 102, afilter 103, a calculator 301, a temporary buffer 302, and adetermination unit 303. The image decoding apparatus 300 is differentfrom the image decoding apparatus according to the first embodiment inthat the image decoding apparatus 300 adaptively performs switchingbetween a filtered decoded pixel block and a non-filtered decoded pixelblock. The following is an explanation of differences in operations ofthe units from the image decoding apparatus according to the firstembodiment.

The decoder 101 outputs a decoded pixel block to the reference linememory 102, the filter 103, the calculator 301, and the determinationunit 303.

The filter 103 receives the decoded pixel block from the decoder 101,and receives reference pixels from the reference line memory 102. Thefilter 103 performs filtering on the decoded pixel block using thedecoded pixel block and part of the reference pixels that areperpendicularly adjacent to the decoded pixel block in the scandirection of the image decoding processing. The filter 103 should use atleast a one-pixel line of pixels extending in the scan direction andclosest to the decoded pixel block, among the reference pixels. Thefilter 103 outputs the filtered decoded pixel block to the determinationunit 303.

The calculator 301 receives the decoded pixel block from the decoder101. The calculator 301 calculates a first value that indicates avariation quantity between pixels in the decoded pixel block, and asecond value that indicates a variation quantity between pixels in apixel block that is perpendicularly adjacent to the decoded pixel blockand has been decoded. The calculator 301 outputs the first value to thedetermination unit 303, and outputs the second value to the temporarybuffer 302.

FIG. 7A and FIG. 7B illustrate a pixel block used in the calculator 301.FIG. 7A is a diagram in which the decoded pixel block is viewed as apixel block (lower adjacent pixel block) located on the lower side of anadjacent pixel block, and FIG. 7B is a diagram in which the decodedpixel block is viewed as a pixel block (upper adjacent pixel block)located on the upper side of an adjacent pixel block. The calculator 301calculates the first value and the second value indicating respectivevariation quantities between pixels in the respective pixel blocks. Thevariation quantity may be calculated by using pixel values of pixelsincluded in the pixel block.

The calculator 301 may calculate the first value of the lower adjacentpixel block, for example, in accordance with the following Expression(3).

wQ=|Q(0,2)−2*Q(0,1)+Q(0,0)|+|Q(3,2)−2*Q(3,1)+Q(3,0)|  (3)

In the Expression (3), wQ on the left side indicates a variationquantity (first value) of a pixel value between pixels in the loweradjacent pixel block. Q(X, Y) on the right side indicates a pixel valueof a pixel in the shaded portion in FIG. 7A.

By contrast, the calculator 301 may calculate the second value of theupper adjacent pixel block, for example, in accordance with thefollowing Expression (4).

wP=|Q(0,1)−2*Q(0,2)+Q(0,3)|+|Q(3,1)−2*Q(3,2)+Q(3,3)|  (4)

In the Expression (4), wP on the left side indicates a variationquantity (second value) of a pixel value between pixels in the upperadjacent pixel block. Q(X, Y) on the right side indicates a pixel valueof a pixel in the shaded portion in FIG. 7B.

A pixel block having a large variation quantity of a pixel value betweenpixels is a pixel block including an edge and texture of the image withhigh probability, and a pixel block having a small variation quantity ofa pixel value between pixels is a pixel block of a flat image with highprobability. In addition, a pixel block of a flat image may lackinformation of pixels due to encoding. Further, when pixel blocks offlat images are adjacent to each other, block distortion may occurbetween the pixel blocks.

To sum up, the calculator 301 simultaneously calculates the first valueand the second value from the decoded pixel block. The first value isoutput to the determination unit 303, and used instantly. The secondvalue is stored in the temporary buffer 302 described later, until adecoding processing is performed on a pixel block located on the lowerside of the decoded pixel block and the first value is calculated fromthe pixel block.

The temporary buffer 302 receives the second value from the calculator301. The temporary buffer 302 stores the second value, until a decodingprocessing is performed on a pixel block located on the lower side ofthe decoded pixel block and the first value is calculated from the pixelblock. At a timing at which the first value is calculated from the loweradjacent pixel block illustrated in FIG. 7A, the temporary buffer 302outputs the second value of the upper adjacent pixel block correspondingto the lower adjacent pixel block to the determination unit 303.

The determination unit 303 receives the decoded pixel block from thedecoder 101, and receives the filtered decoded pixel block from thefilter 103. The determination unit 303 also receives the first valuefrom the calculator 301, and receives the second value from thetemporary buffer 302. The determination unit 303 determines which of thedecoded pixel block and the filtered decoded pixel block should beoutput, using the first value and the second value. After thedetermination, the determination unit 303 outputs the determined one ofthe decoded pixel block and the filtered decoded pixel block to anexternal device that is not illustrated, as the output pixel block.

Specifically, the determination unit 303 outputs the filtered decodedpixel block when a sum of the first value and the second value issmaller than a threshold, and outputs the decoded pixel block when thesum of the first value and the second value is equal to or larger thanthe threshold. The second value used in the determination unit 303 is avalue calculated from the past decoded pixel block that is located onthe upper side of the decoded pixel block from which the first value iscalculated. The threshold may be calculated based on parameters forcontrolling quantization of each adjacent pixel block used in thedecoder 101. The determination method may be a method used in H.264/AVCand H.265/HEVC.

As a modification of the image decoding apparatus 300 according to thesecond embodiment, the calculator 301, the temporary buffer 302, and thedetermination unit 303 may be added to the image decoding apparatus 200.The determination unit 303 determines which of the decoded pixel blockand the decoded pixel block on which first filtering and secondfiltering are performed should be output. The determination unit 303outputs one of the decoded pixel block and the decoded pixel block onwhich first filtering and second filtering are performed to an externaldevice that is not illustrated, as the output pixel block.

As another modification, a second calculator and a second determinationunit may be further added to the image decoding apparatus correspondingto the above modification of the image decoding apparatus 300. Thesecond calculator calculates a variation quantity between pixels in thedecoded pixel block, and a variation quantity between pixels in thepreviously decoded pixel block located on the left of the pixel block.The second determination unit determines which of the decoded pixelblock and the decoded pixel block on which second filtering is performedshould be output. The second determination unit outputs one of thedecoded pixel block and the decoded pixel block on which secondfiltering is performed to the first filter 201, as an intermediate pixelblock. The first filter 201 performs the first filtering described aboveon the intermediate pixel block.

As described above, the image decoding apparatus according to the secondembodiment includes additional processing added to the image decodingapparatus according to the first embodiment. In the additionalprocessing, it is determined which of the decoded pixel block and thefiltered decoded pixel block should be output. With this structure, theimage decoding apparatus can avoid processing on a region on whichfiltering should not be performed, and thus is expected to improve thesubjective image quality of the output pixel block.

The image decoding apparatus is also capable of calculating in advance avariation quantity between pixels used for determination processing on apixel block located on the lower side of the decoded pixel block. Atemporary buffer that stores variation quantities between pixels has amemory circuit scale smaller than that of a memory for storing pixelblocks. For this reason, the image decoding apparatus requires no memorywith a large memory circuit scale to store pixel blocks, and suppressesan increase in the memory circuit scale.

Third Embodiment

As illustrated in FIG. 8, an image decoding apparatus 400 according to athird embodiment includes a decoder 101, a reference line memory 102, afilter 103, a determination unit 303, and a calculator 401. The imagedecoding apparatus 400 is different from the image decoding apparatusaccording to the second embodiment, in that the image decoding apparatus400 does not include a temporary buffer 302. The following is anexplanation of differences in operations in the units from the imagedecoding apparatus according to the second embodiment.

The decoder 101 outputs a decoded pixel block to the reference linememory 102, the filter 103, the calculator 401, and the determinationunit 303.

The reference line memory 102 outputs reference pixels to the decoder101, the filter 103, and the calculator 401.

The calculator 401 receives the decoded pixel block from the decoder101, and receives the reference pixels from the reference line memory102. The calculator 401 calculates a first value indicating a variationquantity between pixels in the decoded pixel block, and a second valueindicating a variation quantity between pixels of reference pixelsadjacent to the decoded pixel block. The calculator 401 outputs thefirst value and the second value to the determination unit 303.

Specifically, as illustrated in FIG. 9, the calculator 401 may calculatethe first value and the second value using a pixel line P of 1×4 pixels,and a line of 1×4 pixels in a decoded pixel block Q adjacent to thepixel line P. The calculator 401 may calculate the first value and thesecond value indicating variation quantities of pixel values of adjacentpixels, for example, in accordance with the following Expression (5) andExpression (6), respectively.

wQ=|Q(0,0)−Q(1,0)|+|Q(1,0)−Q(2,0)|+|Q(2,0)−Q(3,0)|  (5)

wP=|P(0,0)−P(1,0)|+|P(1,0)−P(2,0)|+|P(2,0)−P(3,0)|  (6)

In the Expression (5), wQ on the left side indicates the first value inthe shaded portion of the decoded pixel block Q. In the Expression (6),wP on the left side indicates the second value in the shaded portion ofthe pixel line P.

The calculator 401 may calculate a variation quantity using pixelsdifferent from the pixels in the shaded portion of FIG. 9, or maycalculate a variation quantity using part of the pixels in the shadedportion. The calculator 401 may also calculate the first variationquantity using the Expression (3) instead of the Expression (5).

The determination unit 303 receives the decoded pixel block from thedecoder 101, and receives the filtered decoded pixel block from thefilter 103. The determination unit 303 also receives the first value andthe second value from the calculator 401.

As a modification of the image decoding apparatus 400 according to thethird embodiment, the determination unit 303 and the calculator 401 maybe added to the image decoding apparatus 200. As another modification,the second calculator and the second determination unit may be furtheradded to the image decoding apparatus corresponding to the abovemodification of the image decoding apparatus 400. Specific operationsthereof are the same as those in the modification of the secondembodiment, and explanation thereof is omitted.

As described above, the image decoding apparatus according to the thirdembodiment uses a calculation method different from that of thecalculator in the second embodiment described above, and thus requiresno temporary buffer to store a variation quantity between pixels of apixel block. Accordingly, the image decoding apparatus suppresses anincrease in the memory circuit scale.

In each of the embodiments described above, the image decoding apparatusmay store part of pixels of the filtered decoded pixel block in thereference line memory, and may perform loop filtering. Such loopfiltering is, expected to improve the prediction performance and theencoding efficiency, because an image with block distortion removed isused in intra prediction.

While certain embodiments have been described, these embodiments havebeen presented by way of example only, and are not intended to limit thescope of the inventions. Indeed, the novel embodiments described hereinmay be embodied in a variety of other forms; furthermore, variousomissions, substitutions and changes in the form of the embodimentsdescribed herein may be made without departing from the spirit of theinventions. The accompanying claims and their equivalents are intendedto cover such forms or modifications as would fall within the scope andspirit of the inventions.

What is claimed is:
 1. An image decoding apparatus comprising: a memorythat stores reference pixels based on pixels included in a decoded pixelblock; a decoder that decodes encoded data in units of pixel blocksusing the reference pixels to generate a first decoded pixel block, thefirst decoded pixel block being adjacent to the reference pixels; and afirst filter that performs a first filtering on only the first decodedpixel block using the first decoded pixel block and part of thereference pixels perpendicularly adjacent to the first decoded pixelblock in a scan direction of image decoding processing.
 2. The apparatusaccording to claim 1, wherein the first filter uses at least a one-pixelline extending in the scan direction and closest to the first decodedpixel block, among the reference pixels perpendicularly adjacent to thefirst decoded pixel block in the scan direction.
 3. The apparatusaccording to claim 1, wherein the memory stores at least a one-pixelline extending in the scan direction and closest to a non-decoded pixelblock, among the reference pixels perpendicularly adjacent to thenon-decoded pixel block in the scan direction.
 4. The apparatusaccording to claim 1, further comprising: a second filter that performsa second filtering on the first decoded pixel block on which the firstfiltering has been performed, using the first decoded pixel block and asecond decoded pixel block, the second decoded pixel block being decodeddirectly before the first decoded pixel block and adjacent to the firstdecoded pixel block.
 5. The apparatus according to claim 4, wherein thesecond filter performs the second filtering on the second decoded pixelblock.
 6. The apparatus according to claim 1, further comprising: acalculator that calculates a first value indicating a variation quantitybetween pixels in the first decoded pixel block, and a second valueindicating a variation quantity between pixels in a third decoded pixelblock perpendicularly adjacent to the first decoded pixel block in thescan direction and having been decoded; and a determination unit thatdetermines which of the first decoded pixel block and the filtered firstdecoded pixel block is output, using the first value and the secondvalue.
 7. The apparatus according to claim 6, wherein the determinationunit determines to output the filtered first decoded pixel block, when asum of the first value and the second value is smaller than a threshold.8. The apparatus according to claim 1, further comprising: a calculatorthat calculates a first value indicating a variation quantity betweenpixels in the first decoded pixel block, and a second value indicating avariation quantity between pixels in the reference pixels adjacent tothe first decoded pixel block; and a determination unit that determineswhich of the first decoded pixel block and the filtered first decodedpixel block is output, using the first value and the second value.
 9. Animage decoding apparatus comprising: a memory that stores referencepixels based on a decoded pixel block perpendicularly adjacent in a scandirection of image decoding processing; a decoder that decodes encodeddata in units of pixel blocks using the reference pixels to generate afirst decoded pixel block, the first decoded pixel block being adjacentto the reference pixels; a first filter that performs a first filteringon the first decoded pixel block using the first decoded pixel block anda second decoded pixel block, the second decoded pixel block beingdecoded directly before the first decoded pixel block and being adjacentto the first decoded pixel block; and a second filter that performs asecond filtering on only the first decoded pixel block on which thefirst filtering has been performed, using the first decoded pixel blockand part of the reference pixels perpendicularly adjacent to the firstdecoded pixel block in the scan direction.
 10. The apparatus accordingto claim 9, wherein the first filter uses at least a one-pixel lineextending in the scan direction and closest to the first decoded pixelblock, among the reference pixels perpendicularly adjacent to the firstdecoded pixel block in the scan direction.
 11. The apparatus accordingto claim 9, wherein the memory stores at least a one-pixel lineextending in the scan direction and closest to a non-decoded pixelblock, among the reference pixels perpendicularly adjacent to thenon-decoded pixel block in the scan direction.
 12. The apparatusaccording to claim 9, wherein the first filter performs the firstfiltering on the second decoded pixel block.
 13. The apparatus accordingto claim 9, further comprising: a calculator that calculates a firstvalue indicating a variation quantity between pixels in the firstdecoded pixel block, and a second value indicating a variation quantitybetween pixels in a third decoded pixel block perpendicularly adjacentto the first decoded pixel block in the scan direction and having beendecoded; and a determination unit that determines which of the firstdecoded pixel block and the filtered first decoded pixel block isoutput, using the first value and the second value.
 14. The apparatusaccording to claim 13, wherein the determination unit determines tooutput the filtered first decoded pixel block, when a sum of the firstvalue and the second value is smaller than a threshold.
 15. Theapparatus according to claim 9, further comprising: a calculator thatcalculates a first value indicating a variation quantity between pixelsin the first decoded pixel block, and a second value indicating avariation quantity between pixels in the reference pixels adjacent tothe first decoded pixel block; and a determination unit that determineswhich of the first decoded pixel block and the filtered first decodedpixel block is output, using the first value and the second value. 16.An image decoding method comprising: storing, in a memory, referencepixels based on pixels included in a decoded pixel block; decodingencoded data in units of pixel blocks using the reference pixels togenerate a first decoded pixel block, the first decoded pixel blockbeing adjacent to the reference pixels; and performing a first filteringon only the first decoded pixel block using the first decoded pixelblock and part of the reference pixels perpendicularly adjacent to thefirst decoded pixel block in a scan direction of image decodingprocessing.
 17. The method according to claim 16, wherein the performingthe first filtering uses at least a one-pixel line extending in the scandirection and closest to the first decoded pixel block, among thereference pixels perpendicularly adjacent to the first decoded pixelblock in the scan direction.
 18. The method according to claim 16,wherein the storing in the memory stores at least a one-pixel lineextending in the scan direction and closest to a non-decoded pixelblock, among the reference pixels perpendicularly adjacent to thenon-decoded pixel block in the scan direction.
 19. The method accordingto claim 16, further comprising: performing a second filtering on thefirst decoded pixel block on which the first filtering has beenperformed, using the first decoded pixel block and a second decodedpixel block, the second decoded pixel block being decoded directlybefore the first decoded pixel block and adjacent to the first decodedpixel block.
 20. The method according to claim 19, wherein theperforming the second filter performs the second filtering on the seconddecoded pixel block.